Motor endplate position of rat gastrocnemius muscle
Aarnoud J. Dekhuijzen BSc
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorPetrus A. van Koetsveld BSc
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorGuustaaf C. Baan
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorReinout D. Woittiez PhD
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorCorresponding Author
Dr. Peter A. Huijing PhD
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, P.O. Box 7101, 1007 MC Amsterdam, The NetherlandsSearch for more papers by this authorAarnoud J. Dekhuijzen BSc
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorPetrus A. van Koetsveld BSc
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorGuustaaf C. Baan
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorReinout D. Woittiez PhD
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Search for more papers by this authorCorresponding Author
Dr. Peter A. Huijing PhD
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, Amsterdam, The Netherlands
Department of Functional Anatomy, Interfaculty of Physical Education, Free University, P.O. Box 7101, 1007 MC Amsterdam, The NetherlandsSearch for more papers by this authorAbstract
In this study, the relative endplate position of fibers of rat gastrocnemius caput mediale (GM) muscle was determined by counting numbers of sarcomeres. Isolated fibers were teased from the proximal, intermediate, and distal regions of the muscle. Endplates of distal fibers were located on the proximal third of their lengths. Endplates of intermediate fibers were located at half fiber length, and for proximal fibers, a variable endplate position was obtained: in half of the muscles studied, endplates occurred around the proximal one-third and in the other half near the midpoint of the fiber. Endplate position relative to fiber length was thus found to be dependent on the region of the muscle. Changes in the orientation of endplate zone relative to the muscle belly is likely to take place with changes in muscle length, as shown by a planimetric muscle model. It is argued that architecture of pennate muscles may highly affect characteristics of motor unit potentials.
References
- 1 Aquilonius SM, Askmark H, Gillberg PG, Nandedkar S, Olsson Y, Stålberg E: Topographical localization of motor endplates in cryosections of whole human muscles. Muscle Nerve 7: 287–293 1984.
- 2 Bekoff A, Betz, WJ: Physiological properties of dissociated muscle fibres obtained from innervated and denervated adult rat muscle. J Physiol (Lond) 271: 25–40 1977.
- 3 Bennett MR: Development of neuromuscular synapses. Physiol Rev 63: 915–1048 1983.
- 4 Bennett MR, Pettigrew AG: The formation of synapses in striated muscle during development. J Physiol (Lond) 241: 515–545 1977.
- 5 Bigland-Ritchie B, Donovan EF, Roussos CS: Conduction velocity and EMG power spectrum changes in fatigue of sustained maximal efforts. J Appl Physiol 51: 1300–1305 1981.
- 6 Buchthal F, Guld C, Rosenfalck P: Multielectrode study of the territory of a motor unit. Acta Physiol Scand 39: 83–104 1957.
- 7 Close RL: Dynamic properties of mammalian muscles. Physiol Rev 52: 129–197 1972.
- 8 Coërs C, Woolf AL: Normal histology of the intramuscular nerves and nerve endings, in C Coërs, AL Woolf (eds): The Innervation of Muscle. Oxford, Blackwell, 1959, pp 12–41.
- 9 Csillik B: Methods, in B Csillik (ed): Functional Structure of the Post-Synaptic Membrane in the Myoneural Junction. Budapest, Publishing House of the Hungarian Academy of Sciences, 1965, p. 130.
- 10 Csillik B, Kása P: Localisation of acetylcholine esterase in the guinea pig cerebellar cortex. Acta Neuroveg (Wien) 29: 289–296 1967.
- 11 Dunn OJ: Multiple comparisons using rank sums. Technometrics 6: 241–252 1964.
- 12 Galvas PE, Gonyea WJ: Motor-end-plate and nerve distribution in a histochemically compartmentalized pennate muscle in the cat. J Anat 159: 147–156 1980.
- 13 Griep PAM, Boon KL, Stegeman DF: A study of the motor unit action potential by means of computer simulation. Biol Cybern 30: 221–230 1978.
- 14 Holewijn M, Plantinga P, Woittiez RD, Huijing PA: In vivo bundle length and the number of sarcomeres of the m. gastrocnemius of the rat. J Anat 137: 433–434 1983.
- 15 Holewijn M, Plantinga P, Woittiez RD, Huijing PA: The number of sarcomeres and architecture of the m. gastrocnemius of the rat. Acta Morphol Neerl Scand 22: 257–263 1984.
- 16 Huijing PA: Bundle length, fibre length and sarcomere number in human gastrocnemius. J Anat 133: 132, 1981.
- 17 Huijing PA: The architecture of the human gastrocnemius muscle and some functional consequences. Acta Anat 123: 101–107 1985.
- 18 Huijing PA, Woittiez RD: The effect of architecture on skeletal muscle performance: a simple planimetric model. Neth J Zool 34: 21–32 1984.
- 19 Huijing PA, Woittiez RD: Notes on planimetric and threedimensional muscle models. Neth J Zool (in press).
- 20 Kruskal WH, Wallis WA: Use of ranks in one criterion variance analysis. J Stat Assoc 47: 583–621 1952.
- 21 Lindström LH, Magnusson RI: Interpretation of myoelectric power spectra: a model and its applications. Proc IEEE 65: 653–662 1977.
- 22 Martin AR: The effect of change in length on conduction velocity in muscle. J Physiol (Lond) 125: 215–220 1954.
- 23 Mazur P: Cryobiology: the freezing of biological systems. Science 168: 939–942 1970.
- 24 Menz LJ, Luyet BJ: An electron microscope study of the distribution of ice in single muscle fibers frozen rapidly. Biodynamica 8: 261–294 1961.
- 25 Menz LJ, Luyet BJ: Electron microscope study of the mechanism of formation of irregular bands in muscle undergoing thaw rigor. Biodynamica 9: 305–310 1965.
- 26 Naeije M, Zorn H: Relation between EMG power spectrum shifts and muscle fibre action potential conduction velocity changes during local muscular fatigue in man. Eur J Appl Physiol 50: 23–33 1982.
- 27 Rau G, Reucher H: Muscular activity and surface EMG, in SM Perren, E Schneider (eds): Selected Proceedings of the Fourth Meeting of the European Society of Biomechanics. Dordrecht, Martinus Nijhoff (in press).
- 28 Rosenfalck P: Intra- and extracellular potential fields of active nerve and muscle fibres. Acta Physiol Scand (Suppl) 321: 1–168 1969.
- 29 Stålberg E: Macro EMG. Muscle Nerve 6: 619–630 1983.
- 30 Williams PE, Goldspink PE: Longitudinal growth of striated muscles fibres. J Cell Sci 9: 751–767 1971.
- 31 Woittiez RD, Huijing PA, Rozendal RH: Influence of muscle architecture on the length-force diagram: a model and its verification. Pfluegers Arch 397: 73–74 1983.
- 32 Woittiez RD, Huijing PA, Rozendal RH: Influence of muscle architecture on the length force diagram of mammalian muscle. Pfluegers Arch 399: 275–279 1983.
- 33 Ypey DL: A topographical study of the distribution of endplates in cutaneous pectoris, sartorius and gastrocnemius muscles of the frog. J Morphol 155: 327–348 1978.
- 34 Zacks SI: Anatomy of motor endplates, in SI Zacks (ed): The Motor Endplate. Philadelphia, W. B. Saunders, 1964, pp 1–28.
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